biomechanical testing
TRANSCRIPT
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Rowing technique improvement usingbiomechanical testing
2011 Dr. Valery Kleshnev
Contents1. Introduction.............................................................................................................................1
2. Level 1. Basic quantitative assessment ....................................................................................2
3. Level 2. Detailed qualitative assessment..................................................................................3
3.1. Boat velocity and acceleration .........................................................................................33.2. Pattern of force application (Force Curve) .......................................................................4
3.3. Oar handling skills...........................................................................................................5
3.4. Rowing style....................................................................................................................6
3.5. Synchronisation of the crew.............................................................................................7
4. Level 3. Advanced assessment and treatment with immediate feedback................................... 8
4.1. Static feedback ................................................................................................................8
4.2. Interactive feedback.........................................................................................................84.3. Immediate (real time) feedback........................................................................................9
5. Level 4. Special purpose biomechanical research ....................................................................96. Methods ..................................................................................................................................9
6.1. Types of biomechanical service .......................................................................................96.1.1. In training environment............................................................................................9
6.1.2. In race environment .................................................................................................9
6.1.3. Specialised research testing......................................................................................9
6 2 T t P d 9
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6 2 Test Procedures 9
2
Validity of the measurements. We need to know exactly WHAT we measure and WHAT FORwe need this data;
Accuracy and repeatability. The margins between worlds medallists are measured in 0.01%.
What is the benefit of taking less accurate measurements? The methods must be as unobtrusive as possible, otherwise we will measure not a real rowing,
but obstructed rowing;
Analysis methods must follow common definitions of the variables and derivative parameters.This will make them comparable and meaningful. We will be able to evaluate rowing technique
better and use all available knowledge;
Feedback information must be clear, meaningful, flexible, it should suit different coaches
needs. Data format should allow effective storage for future comparison.Rowing technique can be improved using biomechanical testing at various levels, which defer by
depth, complexity and time consumption.
2. Level 1. Basic quantitative assessmentAt the first level only basic variables of rowing technique are assessed. To achieve a target boat speed,
rowers need to produce certain power, which is a combination of three main variables:
Stroke rate. Drive length; Force application;
Whale the stroke rate can be easily measured with a stopwatch, the drive length (rowing angles) and
force application can be measured accurately only by special biomechanics equipment. Usually, the
main quantitative variables are compared with some target values, so called Biomechanical Gold
Standards (see Table 4 in the appendices) and presented like Table 1 below:
Table 1 Evaluation of the results of Biomechanical testing
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102
104
106
108
110
112
114
116
250 500 750 1000 1250 1500 1750 2000
Stroke
Seat 3
Seat 2Bow
Total Angle (deg)
Race section
200
250
300
350
400
450
500
250 500 750 1000 1250 1500 1750 2000
Stroke
Seat 3
Seat 2Bow
Average Force (N)
Race section
Figure 1. Examples of biomechanical assessment in a race environment.
3. Level 2. Detailed qualitative assessmentAt this level patterns also called profiles or curves of biomechanical variables are analysed.
BioRowTel software produce typical or normalised profiles during the stroke cycle, which is used for
deriving discrete values.
3.1. Bo at veloci ty and accelerat ion
Boat velocity if a resultant variable, which incorporate both rowers efforts and effect of external
environment. Boat velocity is usually analysed in conjunction with boat acceleration, which are closelyrelated: boat velocity is integral of the boat acceleration. Boat acceleration is directly related to the
force applied to the boat hull and
Boat Velocity (m/s)
M i l
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The pattern of instantaneous boat acceleration during the stroke cycle is a very informative
characteristic of a crew and could be used for evaluation of the rowing technique? Figure 3 shows atypical pattern and its discrete characteristics. Each characteristic can be evaluated by its timing. Peaks
and humps can also be evaluated by its magnitude.
Figure 4. Profiles of the boat acceleration in two crews of different level.Obviously, we are interested to know how above characteristics related to the performance of a
crew, efficiency and effectiveness of rowing technique. Fig.2 shows comparison of the boat
acceleration patterns of two pairs at the stroke rate 39 str/min. The better crew 1 (Olympic champions)
have the following differences from the crew 2 (National level pair):
Later time of Zero before catch criterion, which is related to later beginning of the push to thestretcher during recovery and longer acceleration of the seat towards the stern before catch.
D N ti k hi h i l t d t ti l ki k t th t t h
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-12
-9
-6
-3
0
3
6
0.2 0.4 0.6 0.8 1.0 1.2 1.4
1 (Olympic champions)
2 (National level)
Drive
Boat Acceleration (m/s )
Time (s)
FinishCatch
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water. At a higher stroke rate, it usually requires a shorter angle to achieve 30% of max. force (r = -
0.44), but a longer angle to bury the blade. (The vertical catch slip increases, r = 0.20).
Figure 5. Typical force curve and its criteria.Values of 30% and 70% of the maximum force were usually used as the criteria for the force
gradient. We define the catch gradient as an angle, through which the oar travels from the catch pointto the point, where the force Achieves the criterion (A30and A70). The release gradient is defined as
an angle from the point, where the force Drops below the criterion to the finish of the drive (D70and
D30). Parameter A100reflects the position of the peak force and can be used as a definition of a front
loaded drive (RBN 2006/06). Why were values of 30% and 70% used as the criteria? The first of
them was adopted from fixed criteria (100N for sculling and 200N for sweep), which were
traditionally used in Australia, adjusted to accommodate various categories of athlete in both scullingand rowing. The purpose of this parameter was to determine how quickly the blade grips the water. We
f d th t A30 has a correlation ith the efficienc f th bl d ( 0 34) Ram l li htl
30%
70%
Force
Oar Angle
Fmax.=100%
A30A70
D30
D70A100
Faver
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Figure 6. Definition of the vertical angle of the oar.The trajectory of the blade relative to the water level can be plotted using the above reference system
and the criteria of the blade trajectory can be defined, which could be used for evaluation of the
rowers blade-work skills.
i i fi f i f i i i
Vertical Angle (deg)
0
HorizontalAngle
Catch slips Release slips
Water level
Recovery
Drive
-3
A
B
CD
E
FG
H
I
Effective angles
Positive VA
Water Level
Negative VA
Y
XVA = 0
+
-
Horizon
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Figure 8. Typical profiles of the body segments velocities.Simultaneous work of the legs and trunk produces a more rectangular shape of the power curve,
but the peak power is lower. More even pressure on the blade improves its propulsive efficiency.
However, slower and more static movement of the legs and trunk does not allow the delivery of the
optimal power.Sequential work of the legs and trunk produce a triangular shape of the power curves and higher
peak power values. This leads to higher slippage of the blade through the water that causes energy
losses. However, lower blade propulsive efficiency can be more than compensated by higher values of
force and power produced per kg of body weight. Active usage of the trunk produces even more
power, so the Rosenberg style can be considered as the most powerful rowing style.
Emphasis on the legs or trunk affects the position of the force and power peaks. Styles with legemphasis allow a quicker increase of the force and earlier peak of the force curve. This improves the
i iti l b t l ti i h D3 (RBN 1 2/2004) d k th d i ti i ff ti
Velocity (m/s)
Angle (deg)
Max. Trunk Speed
Max. Legs
Speed
Max. Arms
Speed
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Figure 9. Examples of a good (left) and bad (right) synchronisation in two crews.Figure 9 shows pat-terns of the handle velocity in two mens fours:
The first crew (a) of World medallists level has very good synchronisation at the catch (max.
time difference T=12 ms) and finish (T=13 ms). The second crew (b) of a club level has poor syn-chronisation in both the catch (T= 34ms)
and fin-ish (T= 61ms).
4. Level 3. Advanced assessment and treatment with immediatefeedback
Feedback information for the coaches and athletes can be given in three forms: static, interactive andimmediate (real time).
4.1. Static feedbac k
The main form of the static feedback is a report as a hard copy or in electronic form.
Each report should contain a cover page with the following information: date and place ofbiomechanical measurements, boat type and rowers category, coach and crew names, environmental
and rigging constants.
-2
-1
0
1
2
3
Stroke Td= 0.822sSeat 3 Td= 0.827sSeat 2 Td= 0.827sBow Td= 0.825s
Time (s)
Handle Velocity (m/s)
1.0
Fig.1, a
Catch
Finish -2
-1
0
1
2
3
1.0Stroke Td= 0.841sSeat 3 Td= 0.845sSeat 2 Td= 0.785sBow Td= 0.809s
Time (s)
Handle Velocity (m/s) Fig.1, b
Catch
Finish
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4.3. Immed iate (real t ime) feedbac k
Immediate or real time feedback can be provided by means of displaying biomechanical, video or both
(overplayed) types of information. Two sorts of devices can be used for immediate feedback during
on-water rowing: Portable displays mounted in the boat. These devices are preferable for displaying numerical
and graphical data acquired from biomechanical system.
Head-mounted personal monitors. Because of better eye-contact these devices can be used forimmediate feedback using video.
The main principles of immediate feedback:
The information must be meaningful for rowers. They must understand what does it mean and
what their target is. Sufficient minimum of information should be provided. Athletes should not be overloaded with
in information.
The main target is to connect feedback with rowers perceptions and improve them, but not toreplace perceptions with feedback.
5. Level 4. Special purpose biomechanical researchMany other biomechanical variables can be measured: Foot-stretcher forces in 2D and 3D; Vertical force at the seat; Vertical forces at the handle and the gate; Rudder rotation angle; Electromyography (EMG) of the main muscle groups.
These measurements are usually used in special research studies for in-depth investigation of Rowing
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1. Step-rate protocol (SP) consists of five 250m pieces with increasing of the stroke rate: 20, 24,28, 32, 36 str/min. Rest time is until recovery (usually 3-5 min).
2. Race protocol (RP) consists of one full-effort race piece 2000m. The samples are to be taken at
each 250m section of the race.3. Free protocol measurements can include any sorts of workload. They are useful for
experimenting with rowing technique and feedback methods.
Standard tests are important for longitudinal tracking of rowers technique and for comparison of
different athletes and groups. It is recommended performing them for all rowers 3-6 times a year.
6.3. Ath lete / Environmen t con dit ions
Athletes must be in good health and adequately recovered after previous training session.
Biomechanical testing in rowing can be conducted only in adequate environmental conditions:
Wind speed is not higher than 5 m/s, Temperature is in a range 0-40 Co, There is no heavy rain, thunderstorm or hailstorm.
6.4. Telemetry sys tem
The current BioRowTel v4.5 data acquisition system has the following specifications:
Sampling frequency 25-100Hz; Analogue-to-digital converter 14 bits, Number of channels is scalable from 24 for 1x and 2- up to 64 for 4x and 8+. Data logging with memory size 2Gb is enough to store more than 100 hours of data in
training and race modes;
Battery life is up to 8 hours. Radio-transmission can be used for a real-time feedback to coaches.
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6.5.5. Environmental transducers
Wind velocity and direction transducer. Water temperature.
6.6. Calibration
Calibration of the transducers is the process of acquiring of mathematical equations, which relate
numerical dataNreceived from electronic device with physical valuesPof measured variables. The
main purpose of the calibration is to provide accurate and reliable data. There are two main methods of
the calibration:
Static calibration is performed by means of setting known physical value on the transducer and
recording corresponding reading from data acquisition unit. At least four data points must berecorded, which should cover at least 80% of the transducer range.
Dynamic calibration is performed by means of applying additional pre-calibrated transducerwith parallel data acquisition. Number of points is not limited and at least 80% of the
transducer range must be covered.
Four types of calibration equations can be used. Reliability of each transducer is evaluated using
Pearson correlation rcoefficient between input numbers and physical values obtained during the
calibration process. The correlation coefficient must be higher than 0.99.
6.7. Error An alysis
There are three sorts of errors in biomechanical measurements in rowing: calibration errors, data
acquisition errors (aliasing) and normalisation errors
6.7.1. Calibration errors
There are two main reasons of the calibration errors: non-linearity of transducers and hysteresis.
N li it f t d t t b hi h th 0 25% i th f t
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Point of the start and end of the stroke cycle is defined as a time, when oar angle equal to zero during
recovery phase.Names, dimensions, and definitions of the normalised variables are the same as for the corresponding
raw variables. It is important to use unified structure of the data, which allow information exchangeand storage data in data bases.
6.8.2. Derivative variables
Derivative primary or normalised variables can be calculated using primary or normalised data and the
constants, e.g. normalised power variable can be calculated using force and angle variables and oar
inboard/length constants. See
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7. AppendicesTable 2. Definition of the main variables in rowing biomechanics.
No Variable type and Unit ID Conventions/Comments
1. Normal Gate
ForceN Fgn Component of the gate force perpendicular to the face
of the gate (also perpendicular to the long axis of the
oar when it is fully engaged with the gate). Positive
towards the pin.
2. Normal HandleForce
N Fhn Component of the handle force perpendicular to the oaraxis (also perpendicular to the blade). Positive towards
the bow.3. Shear Gate Force
NFgs Component of the gate force parallel to the face of the
gate in the horizontal plane. Positive is outwards fromthe long axis of the boat (towards the blade).
4. Vertical Gate
ForceN Fgv Component of the gate force parallel to the face of the
gate and perpendicular to the horizontal plane. Positive
upwards.
5. StretcherHorizontal ForceN Ffh
Horizontal component of the stretcher force parallel tothe long axis of the boat. Positive is a force directed
towards the bow.
6. Stretcher Vertical
ForceN Ffv Vertical component of the stretcher force. Positive is a
force on the boat upwards.
7. Horizontal Oar
Angledeg Ah Angle between the long axis of the oar and a line
perpendicular to the long axis of the boat. Zero is
perpendicular to the long axis of the boat. Positive
di ti i h th h dl i l t th b
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Table 3. Definition of derived variables types.
No. Variable Dim. ID Formula Definition,Conventions/Comments
1.
Gate
PropulsiveForce
N Fgpr Fgn cos(Ah) Fgs sin(Ah)
Component of the gate force parallel with
the long axis of the boat. Positive is towardsthe bow
2.Gate
Transverse
ForceN Fgtr
Fgs cos(Ah) +
Fgn sin(Ah)
Component of the gate force in the
horizontal plane perpendicular to the long
axis of the boat. Positive is directedoutwards.
3.
Handle
normal force NFhn
Fgn (Louta
/Loara)
Force of rower on the handle normal to the
long axis of the oar. It can be calculated onthe basis of the gate force measurements.
4.Handle
propulsive
force.N Fhpr
Fhn cos(Ah)
Fga sin(Ah)
Force of rower on the handle along the long
axis of the boat. Positive is towards the
bow.
5.Propulsive
Boat Force NFprop ( ) +
n
FfFgpr0
Net effect of n pin and stretcher forces on
the boat.
6. Boat Yaw deg By Byvdt Rotation of the boat around its vertical axis.Positive yaw is bow displaced towards thestroke side.
7. Boat Pitch deg Bp Bpvdt Rotation of the boat around its transverseaxis. Positive pitch is bow displaced
downwards at the bow.
8. Boat Roll deg Br BrvdtRotation of the boat around its longitudinal
axis. Positive roll is top of the boat
di l d t th b id
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Table 4. Biomechanical standards used at the 1stLevel of assessment.
M1x M2x M4x LM2x M2- M4- M8+ LM4- W1x W2x W4x LW2x W2- W8+
Target speed (Time of2000m) 06:32.5 06:02.1 05:33.2 06:07.2 06:16.5 05:41.0 05:18.6 05:46.2 07:11.5 06:39.5 06:08.5 06:47.0 06:52.9 05:53.1
Racing Stroke Rate (1/min) 37 39 40 36 38 40 41 40 35 37 38 36 36 39
Drive Time (s) 0.90 0.85 0.80 0.93 0.85 0.80 0.78 0.80 0.93 0.88 0.83 0.93 0.88 0.81
Rhythm (%) 54% 54% 54% 55% 53% 53% 53% 53% 54% 54% 54% 55% 53% 53%Catch Angle (deg) -70 -70 -70 -66 -60 -60 -60 58 -66 -66 -66 -63 -58 -58
Release Finish (deg) 44 44 44 44 34 34 34 34 44 44 44 43 34 34
Total Angle (deg) 114 114 114 110 92 92 92 90 110 110 110 106 90 90
Maximal Force (N) 850 850 850 750 760 760 760 660 650 650 650 550 550 550
Average Force (N) 460 460 460 390 380 380 380 340 340 340 340 290 300 300
Rowing Power (W) 550 550 550 500 500 500 500 460 460 460 460 350 400 400
M1x M2x M4x LM2x M2- M4- M8+ LM4- W1x W2x W4x LW2x W2- W8+
Vertical Catch Slip (deg) 9.0 9.0 9.0 9.0 9.0 9.0 9.0 9.0 9.0 9.0 9.0 9.0 9.0 9.0
Vertical Release Slip (deg) 15.0 15.0 15.0 15.0 12.0 12.0 12.0 12.0 15.0 15.0 15.0 15.0 12.0 12.0
Effective Angle (%) 84% 184% 284% 84% 80% 80% 80% 80% 84% 84% 84% 83% 80% 80%Ratio Aver / Max. Forces(%)
54% 54% 54% 55% 50% 50% 50% 50% 52% 52% 52% 53% 51% 51%
Position of Max.Force (% ofTotal Angle)
40%36% 33%
36% 39% 35% 30% 35% 40%36% 33%
40% 40% 32%
Force up to 70%Max (deg) 17.0 17.0 17.0 16.0 14.0 14.0 14.0 13.0 16.0 16.0 16.0 16.0 13.0 13.0
Force down from 70%Max(deg)
25.0 25.0 25.0 24.0 20.0 20.0 20.0 20.0 24.0 24.0 24.0 24.0 20.0 20.0
Legs Travel (m) 0.58 0.58 0.58 0.54 0.60 0.60 0.60 0.54 0.55 0.55 0.55 0.52 0.56 0.56
Legs Max. Speed (m/s) 1.40 1.45 1.50 1.40 1.40 1.45 1.50 1.45 1.30 1.35 1.40 1.30 1.3 1.4